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NWCG FIRELINE HANDBOOK APPENDIX B

FIRE BEHAVIOR

APRIL, 2006 PMS 410-2 NFES 2165

Additional copies of this publication may be ordered from:

National Interagency Fire Center ATTN: Supply

3833 S. Development Avenue Boise, Idaho 83705

Order NFES 2165

B-1

CONTENTS

PURPOSE ...................................................................................... 4

FIRE BEHAVIOR WORKSHEETS .............................................. 5

INPUT 0–Projection Point ......................................................

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10

INPUT 1–Selecting a Fuel Model 10 Fire Behavior Fuel Model Key 12 Fire Behavior Fuel Model Descriptions 16

Grass Group 16 Shrub Group 17 Timber Litter Group 18 Logging Slash Group 19

Table 1–Description of Fuel Models 21

INPUT 2–Fine Dead Fuel Moisture (1-H FDFM) 22

Table 3–Dead Fuel Moisture Content Corrections,

Table 4–Dead Fuel Moisture Content Corrections, Day (0800-1759) February, March, April, August,

Table 5–Fine Dead Fuel Moisture Content Corrections,

Table 2–Reference Fuel Moisture, Day (0800-1959) .........

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25

Day (0800-1959) May, June, July 26

September, October 27

Day (0800-1759) November, December, January 28

INPUT 3–Live Fuel Moisture (LFM) Fuel Models 2, 4, 5, 7 and 10 29

Table 6–Live Fuel (Foliage) Moisture Content % 29

INPUT 4–Midflame Windspeed (MFWS) 30 Diagram 1: 20-Foot Windspeed Adjusted to

Midflame Windspeed Based on Overstory 32 Table 7–Wind Adjustment Table 33 Table 8–Modified Beaufort Scale for Estimating

20-Foot Windspeed 34

INPUT 5–Slope (SLP) 35 Slope Determination Process ...............................................

.............................. 35

Table 9–Map Scale Conversion Factors 36

B-2

CONTENTS (continued)

INPUT 6–Effective Windspeed (EWS) ...................................

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37

FIRE BEHAVIOR OUTPUTS

OUTPUT 1–Rate of Spread .................................................... 38 OUTPUT 2–Heat Per Unit Area 38 OUTPUT 3–Fireline Intensity 38 OUTPUT 4–Flame Length 38 OUTPUT 5–Spread Distance 38

OUTPUT 6/7–Projected Fire Perimeter and Area 40 Table 10–Perimeter Estimations for Point Source Fires 41 Table 11–Area Estimations for Point Source Fires 44 Diagram 2: Approximate Fire Shapes for Various

Effective Windspeeds 47

OUTPUT 8–Maximum Spotting Distance 48 Nomogram 1–Flame Height 50 Nomogram 2–Flame Duration 51 Nomogram 3–Ratio of Lofted Firebrand Height to

Flame Height .................................................................... ........................

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52 Nomogram 4–Maximum Spotting Distance 53

OUTPUT 9–Probability of Ignition 54 Table 12–Probability of Ignition Table 55

INTERPRETATION OF FIRE BEHAVIOR INFORMATION

Table 13–Fire Severity Related to Fuel Moisture Chart ..... 56 Diagram 3: Fire Behavior Characteristics Chart

(Light Fuel) 57 Diagram 4: Fire Behavior Characteristics Chart

(Heavy Fuel) 58 Table 14–Fire Suppression Interpretations 59

SAFETY AND FIRE BEHAVIOR 60 Look Up/Look Down/Look Around 61

Tables 15 through 78 – Rate of Spread and Flame Length Tables by Fuel Type and Percent Slope 63

B-3

PURPOSE

The purpose of this appendix is to provide some basic fire behavior information that will enable a person with a moderate level of fire behavior training (Introduction to Wildland Fire Behavior Calculations, S-390) to predict and calculate some basic elements of fire behavior and fire size.

Information in this appendix will provide the qualified user with the means to:

• Predict rate of spread (ROS) and flame length (FL) for each Fire Behavior Fuel Model based on the 1-hour timelag dead fuel moisture, live fuel moisture for Fuel Models 2, 4, 5, 7 and 10, midflame windspeed and percent slope.

• Estimate the area and perimeter of a fire, given inputs of spread distance (rate of spread x time) and midflame windspeed.

• Predict maximum spotting distance and probability of ignition.

• Provide worksheets for fire behavior prediction.

The Fire Behavior Worksheet is on page B-5. Other worksheets that help track fire behavior input and output date (Fine Dead Fuel Moisture/Probability of Ignition, Wind Adjustment, Slope, Map-Spread, Size, Spotting, and Map-Spot) are provided on pages B-6 through B-9. Pages B-10 through B-37 go over the six required input items on the Fire Behavior Worksheet and B-38 through B-55 cover the output items.

It is imperative that the user of information contained in this appendix know the assumptions, limitations, and appropriate uses of fire behavior prediction models and is able to recognize how environmental factors and processes affect fire behavior predictions and safety.

B-4

FIRE BEHAVIOR WORKSHEET

NAME OF FIRE ___________FIRE PRED SPEC_____________ DATE____________________ TIME_______________________

PROJ PERIOD DATE_______PROJ TIME FROM _____TO____

INPUT 0 PP PROJECTION POINT ___ ___ ___

1 MODEL# FUEL MODEL NUMB (1-13) ___ ___ ___

2 1H-FDFM FINE DEAD FUEL MOIST, % ___ ___ ___

3 LFM LIVE FUEL MOISTURE, % ___ ___ ___

4 MFWS MIDFLAME WINDSPD, mi/h ___ ___ ___

5 SLP SLOPE, % ___ ___ ___

6 EWS EFFECTIVE WNDSPD, mi/h ___ ___ ___

OUTPUT 1 ROS RATE OF SPREAD, ch/h ___ ___ ___

2 HA HEAT PER UNIT AREA, ___ ___ ___ Btu/sq ft

3 FLI FIRELINE INTENSITY, ___ ___ ___ Btu/ft/s

4 FL FLAME LENGTH, ft ___ ___ ___

5 SD SPREAD DISTANCE, ch ___ ___ ___ MAP SPREAD DIST, in

6 PER PERIMETER, ch ___ ___ ___

7 AC AREA, ac ___ ___ ___

8 SPOT MAX SPOTTING DIST, mi ___ ___ ___ MAP DIST SPOT, in ___ ___ ___

9 PIG PROB OF IGNITION, % ___ ___ ___

B-5

FINE DEAD FUEL MOISTURE/PROBABILITY OF IGNITION WORKSHEET

INPUT 0 PP PROJECTION POINT ____ ____ ____

1 D DAY TIME CALCULATION D D D

2 DB DRY BULB TEMP. °F ____ ____ ____

3 WB WET BULB TEMP. °F ____ ____ ____

4 DP DEW POINT, °F ____ ____ ____

5 RH RELATIVE HUMIDITY, % ____ ____ ____

6 RFM REFERENCE FUEL ____ ____ ____ MOIST, % (TABLE 2)

7 M O MONTH ____ ____ ____

8 SH UNSHADED (U) U/S U/S U/S SHADED (S)

9 T TIME ____ ____ ____

10 CH ELEVATION CHANGE B/L/A B/L/A B/L/A

B = 1000' to 2000' below site L = +1000' of site location A = 1000' to 2000' above site

11 ASP ASPECT, (N, E, S, W) ____ ____ ____

12 SLP SLOPE % ____ ____ ____

13 FMC FUEL MOIST CORRECT, % ____ ____ ____ (TABLE 3, 4, OR 5)

OUTPUT 1 1H- FINE DEAD FUEL MOIST, % ____ ____ ____

FDFM (line 6 + line 13)

2 PIG PROB OF IGNITION, % ____ ____ ____ (TABLE 12)

B-6

WIND ADJUSTMENT WORKSHEET


1 20' W 20-FT WINDSPEED, mi/h ____ ____ ____

2 MODEL # FUEL MODEL # (1-13) ____ ____ ____

3 SHLTR WIND SHELTERING ____ ____ ____

1=Unsheltered 2=Partially Sheltered 3=Fully Sheltered, Open 4=Fully Sheltered, Closed

4 WAF WIND ADJUST FACTOR ____ ____ ____ (TABLE 7)

OUTPUT 1 MFWS MIDFLAME WNDSPD, mi/h ____ ____ ____

(line 1 x line 4)

SLOPE WORKSHEET


1 CON INT CONTOUR INTERVAL ____ ____ ____

2 SLC MAP SCALE ____ ____ ____

3 CF CONVERSION FACTOR, ____ ____ ____ ft/in

4 # INTVLS # CONTOUR INTERVALS ____ ____ ____

5 RISE RISE IN ELEVATION ____ ____ ____

6 M D MAP DISTANCE, in ____ ____ ____ (Between Points)

7 HZGD HORIZ GROUND DIST, ft ____ ____ ____

OUTPUT 1 SLP % SLOPE, % ____ ____ ____

B-7

MAP-SPREAD WORKSHEET


1 ROS RATE OF SPREAD, ch/h ____ ____ ____

2 PT PROJECTION TIME, hr ____ ____ ____

3 SDCH SPREAD DISTANCE, ch ____ ____ ____ (line 1 x line 2)

4 SDFT SPREAD DISTANCE, ft ____ ____ ____ (line 3 x 66 ft/ch)

5 SCL MAP SCALE ____ ____ ____

6 CF CONVERSION FACTOR, ____ ____ ____ ft/in (See Map Scale Conversion)

OUTPUT 1 M D MAP SPREAD DIST, in ____ ____ ____

(line 4 divided by line 6)

SIZE WORKSHEET


1 ROS RATE OF SPREAD, ch/h ____ ____ ____

2 EWS EFFECTIVE WINDSPD, mi/h ____ ____ ____

3 PT PROJECTION TIME, hr ____ ____ ____

4 SD SPREAD DISTANCE, ch ____ ____ ____ (line 1 x line 3 = line 4)

OUTPUT 1 PER PERIMETER, ch ____ ____ ____

2 AC AREA, ac ____ ____ ____

B-8

SPOTTING WORKSHEET

MAP-SPOT WORKSHEET


1

2

3

SPOTMI SPOTTING DISTANCE, mi

SPOTFT SPOTTING DISTANCE, ft (line 1 x 5,280 ft)

SCL MAP SCALE

____

____

____

____

____

____

____

____

____

4 CF CONVERSION FACTOR, ft/in

____ ____ ____

OUTPUT 1 SPOT MAP DISTANCE SPOT, in

(line 2 divided by line 4) ____ ____ ____

B-9

COMPLETING THE FIRE BEHAVIOR WORKSHEET

INPUT 0: Projection Point (PP)

Assign a number or letter to designate the projection point location and enter as Input 0 on the Fire Behavior Worksheet on page B-5.

INPUT 1: Fuel Model (Model #)

• Using the guidelines below, proceed through the fuel model key and descriptions which follow and select a fuel model and enter as Input 1 on the Fire Behavior Worksheet on page B-5.

• Determine the primary carrier of fire.

• Determine which stratum of the surface fuels is most likely to carry the spreading fire (grass, needle litter, leaves, logging slash, etc.).

• Determine the appropriate fuel group/general vegetation type; i.e., Grass (Models 1-3), Shrub (Models 4-7), Timber Litter (Models 8-10), or Logging Slash (Models 11-13).

• Using the fuel model key, determine the appropriate fuel model.

• Go to the fuel model description and determine if it fits.

• If yes, use it and enter into Input 1 on the Fire Behavior Worksheet.

• If no, find another that more closely fits your situation.

• The fuel models used here are those used by Albini (1976)¹ to develop the nomograms published in his paper Estimating Wildfire Behavior and Effects. There are 13 models which are called the Fire Behavior Fuel Models.

¹ Albini Frank A.; Estimating Wildfire Behavior and Effects. Gen. Tech. Report INT-30; 1976.

B-10

They are tuned to the fine fuels that carry the fire and thus describe the conditions at the head of the fire or the flaming front. These models are designed to give predictions for fire spread at a steady rate. It is important to recognize that rate of spread (ROS) and flame length (FL) predictions are estimates and the actual ROS and FL may vary considerably from the predicted.

• Assessment of fire behavior is simpler if a single fuel model is used to describe the fuels in the area. In fact, as experience is gained by observation of fires and estimating their behavior, it is possible to pick the fuel model not only by its description of physical vegetation, but also by its known fire behavior characteristics.

Examples: The fire may be in timbered area, but the timber is relatively open and dead grass, not needle litter, is the stratum carrying the fire. In this case, Fuel Model 2, which is not listed as a timber model, should be considered, or

In the same area if the grass is sparse and there is no wind or slope, the needle litter would be the stratum carrying the fire and Fuel Model 9 would be the better choice.

• Determine the general depth and compactness of the fuel. This information will be needed when using the fuel model key. There are very important considerations when matching fuels, particularly in the grass and timber types.

• Determine which fuel models are present and what their influence on fire behavior is expected to be.

Example: Green fuel may be present, but will it play a significant role in fire behavior? Large fuels may be present, but are they sound, or decaying and breaking up? Do they have limbs and twigs attached or are they bare cylinders? Look for the fine fuels and choose a model that represents their depth, compactness, and to some extent, the amount of live fuel and its contribution to fire. Do not be restricted by the model name or the original intended application.

B-11

FIRE BEHAVIOR FUEL MODEL KEY¹

I. PRIMARY CARRIER OF THE FIRE IS GRASS. Expected rate of spread is moderate to high, with low to moderate fireline intensity (flame length).

A. Grass is fine structured, generally below knee level, and cured or primarily dead. Grass is essentially continuous. SEE THE DESCRIPTION OF MODEL 1.

B. Grass is coarse structured, above knee level (averaging about 3 ft.) and is difficult to walk through. SEE THE DESCRIPTION OF MODEL 3.

C. Grass is usually under an open timber or brush overstory. Litter from the overstory is involved, but grass carries the fire. Expected spread rate is slower than Fuel Model 1 and intensity is less than Fuel Model 3. SEE THE DESCRIPTION OF MODEL 2.

¹ Richard C. Rothermel; How to Predict the Spread and Intensity of Forest and Range Fires. Gen. Tech Report INT-143; June 1983 (NFES 1574).

B-12

II. PRIMARY CARRIER OF THE FIRE IS SHRUB or LITTER BENEATH SHRUB. Expected rates of spread and fireline intensities (flame length) are moderate to high.

A. Vegetative type is southern rough or low pocosin. Shrub is generally 2 to 4 ft. high. SEE THE DESCRIPTION OF MODEL 7.

B. Live fuels are absent or sparse. Brush averages 2 to 4 ft. in height. Brush requires moderate winds to carry fire. SEE THE DESCRIPTION OF MODEL 6.

C. Live fuel moisture can have a significant effect on fire behavior.

1. Shrub is about 2 ft. high, with light loading of brush litter underneath. Litter may carry the fire, especially at low windspeeds. SEE THE DESCRIPTION OF MODEL 5.

2. Shrub is head-high (6 ft.), with heavy loadings of dead (woody) fuel. Very intense fire with high spread rates expected. SEE THE DESCRIPTION OF MODEL 4.

3. Vegetative type is high pocosin. SEE THE DESCRIPTION OF MODEL 4.

B-13

III. PRIMARY CARRIER OFTHE FIRE IS LITTER BENEATH A TIMBER STAND. Spread rates are low to moderate, fireline intensity (flame length) may be low to high.

A. Surface fuels are mostly foliage litter. Large fuels are scattered and lie on the foliage litter, that is, large fuels are not supported above the litter by their branches. Green fuels are scattered enough to be insignificant to fire behavior.

1. Dead foliage is tightly compacted, short needle (2 inches or less) conifer litter or hardwood litter. SEE THE DESCRIPTION OF MODEL 8.

2. Dead foliage litter is loosely compacted long needle pine or hardwoods. SEE THE DESCRIPTION OF MODEL 9.

B. There is a significant amount of larger fuels with attached branches and twigs, or it has rotted enough that it is splintered and broken. The larger fuels are fairly well distributed over the area. Some green fuel may be present. Overall depth of the fuel is primarily below the knees, but some fuel may be higher. SEE THE DESCRIPTION OF MODEL 10.

IV. PRIMARY CARRIER OF THE FIRE IS LOGGING SLASH. Spread rates are low to high, fireline intensities (flame lengths) are low to very high.

A. Slash is aged and overgrown.

1. Slash is from hardwood trees. Leaves have fallen and cured. Considerable vegetation (tall weeds) has grown in amid the slash and has cured or dried out. SEE THE DESCRIPTION OF MODEL 6.

2. Slash is from conifers. Needles have fallen and considerable vegetation (tall weeds and some shrubs) has overgrown the slash. SEE THE DESCRIPTION OF MODEL 10.

B-14

B. Slash is fresh (0-3 years) and not overly compacted.

1. Slash is not continuous. Needle litter or small amounts of grass or shrubs must be present to help carry the fire, but primary carrier is still slash. Live fuels are absent or do not play a significant role in fire behavior. The slash depth is about 1 ft. SEE THE DESCRIPTION OF MODEL 11.

2. Slash generally covers the ground (heavier loadings than Model 11), though there may be some bare spots or areas of light coverage. Average slash depth is about 2 ft. Slash is not excessively compacted. Approximately one-half of the needles may still be on the branches but are not red. Live fuels are absent, or are not expected to affect fire behavior. SEE THE DESCRIPTION OF MODEL 12.

3. Slash is continuous or nearly so (heavier loadings than Model 12). Slash is not compacted and has an average depth of 3 ft. Approximately one-half of the needles are still on the branches and are red, OR all the needles are on the branches but they are green. Live fuels are not expected to influence fire behavior. SEE THE DESCRIPTION OF MODEL 13.

4. Same as 3, EXCEPT all the needles are attached and are red. SEE THE DESCRIPTION OF MODEL 4.

B-15

FIRE BEHAVIOR FUEL MODEL DESCRIPTIONS²

• Grass Group

Fuel Model 1 (1 foot deep) Fire spread is governed by the fine herbaceous fuels that have cured or are nearly cured. Fires are surface fires that move rapidly through cured grass and associated material. Very little shrub or timber is present, generally less than one-third of the area.

Grasslands and savanna are represented along with stubble, grass-tundra, and grass-shrub combinations that meet the above area constraint. Annual and perennial grasses are included in this fuel model.

Fuel Model 2 (1 foot deep) Fire spread is primarily through the fine herbaceous fuels, either curing or dead. These are surface fires where the herbaceous material, besides litter and dead-down stemwood from the open shrub or timer overstory, contribute to the fire intensity. Open shrub lands and pine stands or scrub oak stands that cover 1/3 to 2/3 of the area may generally fit this model but may include clumps of fuels that generate higher intensities and may produce firebrands. Some pinyon-juniper may be in this model.

Fuel Model 3 (2.5 feet deep) Fires in this fuel are the most intense of the grass group and display high rates of spread under the influence of wind. The fire may be driven into the upper heights of the grass stand by the wind and cross over standing water. Stands are tall, averaging about 3 feet, but considerable variation may occur. Approximately one-third or more of the stand is considered dead or cured and maintains the fire.

² Anderson, Hal E.; Aids to Determining Fuel Models for Estimating Fire Behavior. Gen. Tech Report INT-122, 1982.

B-16

• Shrub Group

Fuel Model 4 (6 feet deep) Fire intensity and fast spreading fires involve the foliage and live and dead fine woody materials in the crowns of a nearly continuous secondary overstory. Examples are stands of mature shrub, 6 or more feet tall, such as California mixed chaparral, the high pocosins along the east coast, the pine barrens of New Jersey or the closed jack pine stands of the north-central states. Besides flammable foliage, there is dead woody material in the stand that significantly contributes to the fire intensity. Height of stands qualifying for this model vary with local conditions. There may be also a deep litter layer that confounds suppression efforts.

Fuel Model 5 (2 feet deep) Fire is generally carried in the surface fuels made up of litter cast by the shrubs and the grasses or forbs in the understory. Fires are generally not very intense as surface fuel loads are light, the shrubs are young with little dead material, and the foliage contains little volatile material. Shrubs are generally not tall, but nearly cover the entire area. Young, green stands with little or no deadwood such as laurel, vine maple, alder, or even chaparral, manzanita, or chamise are examples. As the shrub fuel moisture drops, consider using a Fuel Model 6.

Fuel Model 6 (2.5 feet deep) Fires carry through the shrub layer where the foliage is more flammable than Fuel Model 5, but require moderate winds (>8 mi/h) at midflame height. Fire will drop to the ground at low windspeeds or openings in the stand. Shrubs are older, but not as tall as shrub types of Model 4, nor do they contain as much fuel as Model 4. A broad range of shrub conditions is covered by this model. Typical examples include intermediate stands of chamise, chaparral, oak brush, low pocosins, Alaskan spruce taiga, and shrub tundra. Cured hardwood slash can be considered. Pinyon-juniper shrublands may fit, but may overpredict rate of spread except at high winds (20 mi/h at the 20-foot level).

B-17

Fuel Model 7 (2.5 feet deep) Fire burns through the surface and shrub strata equally. Fire can occur at higher dead fuel moisture contents due to the flammable nature of live foliage. Shrubs are generally 2 to 6 feet high. Examples are Palmettogallberry understory-pine overstory sites, low pocosins, and Alaska Black Spruce-shrub combinations.

• Timber Litter Group

Fuel Model 8 (0.2 foot deep) Slow burning ground fires with low flame heights are generally the case, although an occasional “jackpot” or heavy fuel concentration may cause a flare up. Only under severe weather conditions do these fuels pose fire problems. Closed-canopy stands of short needle conifers or hardwoods that have leafed out support fire in the compact litter layer. This layer is mainly needles, leaves, and some twigs since little undergrowth is present in the stand. Representative conifer types are white pine, lodgepole pine, spruce, true fires, and larches.

Fuel Model 9 (0.2 foot deep) Fires run through the surface litter faster than model 8 and have higher flame height. Both long-needle conifer and hardwood stands, especially the oak-hickory types, are typical. Fall fires in hardwoods are representative, but high winds will actually cause higher rates of spread than predicted because of spotting caused by rolling blowing leaves. Closed stands of long-needled pine like ponderosa, Jeffrey, and red pines or southern pine plantations are grouped in this model. Concentrations of dead-down woody material will contribute to possible torching out of trees, spotting, and crowning activity.

B-18

Fuel Model 10 (1 foot deep) The fires burn in the surface and ground fuels with greater fire intensity than other timber litter models. Dead-down fuels include greater quantities of 3-inch or larger limb wood resulting from over-maturity or natural events that create a large load of dead material on the forest floor. Crowning out, spotting, and torching of individual trees are more frequent in this fuel situation leading to potential fire control difficulties. Any forest type may be considered when heavy down materials are present; examples are insect or diseased stands, wind-thrown stands, over-mature situations with deadfall, and cured light thinning or partial-cut slash.

• Logging Slash Group

Fuel Model 11¹ (1 foot deep) Fires are fairly active in the slash and herbaceous material intermixed with the slash. The spacing of the rather light fuel load, shading from overstory, or the aging of the fine fuels can contribute to limiting the fire potential. Light partial cuts or thinning operations in mixed conifer stands, hardwood stands, and southern pine harvests are considered. Clear-cut operations generally produce more slash than represented here. The 3 inch material is represented by not more than 10 pieces, 4 inches in diameter along a 50-foot transect.

Fuel Model 12¹ (2.3 feet deep) Rapidly spreading fires with high intensities capable of generating firebrands can occur. When fire starts, it is generally sustained until a fuel break or change in fuels is encountered. The visual impression is dominated by slash and much of it is 3 inch material is represented by encountering 11 pieces, 6 inches in diameter, along a 50-foot transect.

¹ When working in Fuel Model 11 or 12 with significant “red” needles attached to limbs, consider using the next heavier model. For example: Fuel Model 11 with “red” needles, use Fuel Model 12.

B-19

Fuel Model 13² (3 feet deep) Fire is generally carried by a continuous layer of slash. Large quantities of >3 inch material are present. Fires spread quickly through the fine fuels and intensity builds up as the large fuels start burning. Active flaming is sustained for long periods and a wide variety of firebrands can be generated. These contribute to spotting problems as the weather conditions become more severe. Clear-cut and heavy partial-cuts in mature and over-mature stands are depicted where the slash load is dominated by the >3 inch material. The total load may exceed 300 tons per acre, but the

INPUT 2: Fine Dead Fuel Moisture (1-H FDFM), %

Fine Dead Fuel Moisture Content is an important input to fire behavior predictions. Fuel moisture measurements are difficult to make in the field; however, estimates can be made from measured or predicted values of dry bulb temperature and relative humidity.

Due to solar radiation differences that exist between aspect, time of year, shading, and the adiabatic difference between position on the slope, it is necessary to calculate an estimate of fuel moisture. This is necessary as the National Fire Danger Rating System (NFDRS) tables used here were developed for “worst case” conditions (summer, 1400, SW aspect, open conditions). These predictions are for fine, dead forest fuels. Heavier fuels can be estimated by other means as needed.

Temperature and humidity are predicted for a specific site (projection point) in relation to a site (site location) where dry bulb temperatures and relative humidity are measured. Since temperature and relative humidity change with elevation, it is necessary to estimate these changes between the projection point and the site location. There are tables to correct for elevation changes of 0 to 2000 feet above or below the site location, but a new site location is needed if the elevation difference between the site location and the projection point exceeds 2000 feet.

Time corrections cannot be made. Temperature and relative humidity must be obtained for the time in question.

The tables may be used to adjust the moisture of fuels in valley bottoms from conditions measured on the slopes above, but do not use weather data taken beneath a valley inversion and attempt to interpolate fuel moistures at drier sites upslope. The corrections are too large and uncertain, and you may get meaningless results.

To use the Fine Dead Fuel Moisture/Probability of Ignition Worksheet on page B-6, complete the following input/output items. Enter the fine dead fuel moisture as Output 1 on the Fine Dead Fuel Moisture/Probability of Ignition Worksheet and as Input 2 on the Fire Behavior Worksheet on page B-5.

B-22

INPUT

0 (Projection Point)—Record the number of the projection point for which a fire behavior prediction is to be made.

1 (Day Time Calculation)—Only day time calculations will be considered.

2 (Dry Bulb Temperature)—Dry bulb temperature is determined for the time period in question, either by measurement or forecast. The site location may or may not be at the projection point. Record temperature in degrees Fahrenheit.

3 (Wet Bulb Temperature)—Wet bulb temperature is determined for the time period in question, either by measurement or forecast. The site location may or may not be at the projection point. Record temperature in degrees Fahrenheit.

4 (Dew Point)—Record dew point for the time period in question.

5 (Relative Humidity)—Record relative humidity for the time period in question.

6 (Reference Fuel Moisture)—Go to Table 2 and determine the reference fuel moisture percent from the intersection of temperature and relative humidity (Inputs 2 and 5). Record as a percent.

7 (Month)—Record the appropriate month.

8 (Unshaded or Shaded)—Circle “U” if fine dead fuels ahead of the projection point are unshaded (50% shading) from solar radiation due to cloud and/or canopy cover.

B-23

9 (Time)—Record the expected time when the projection point will be used to estimate fire behavior. The temperature/RH forecast or measurement must be the same time period as the projection time period.

10 (Elevation Change)—Record the elevation difference between the location of the projection point and the temperature/RH site location and circle:

“B” if the projection point is 1000 to 2000 feet below the site location.

“L” if the projection point is 0 to 1000 feet above or below the site location.

“A” if the projection point is 1000 to 2000 feet above the site location.

If the projection point is more than 2000 feet above or below the site location, get a new forecast or reading.

11 (Aspect)—Record the aspect of the projection point location (north, south, east, or west).

12 (Slope)—Record the slope in percent (%) at the project point. (See pages B-35 and B-36 for determining percent slope.)

13 (Fuel Moisture Correction)—From Input Values 7 through 12 and the appropriate Daytime Correction Tables (Tables 3, 4, or 5) determine fuel moisture correction. Record in percent.

OUTPUT

1 (Fine Dead Fuel Moisture)—Determine the fine dead fuel moisture by adding Input Item 6 and Input Item 13. Record as a percent.

B-24

INPUT 3: Live Fuel Moisture (LFM), %

Live fuel moisture (foliage moisture) is required for Fire Behavior Models 2, 4, 5, 7 and 10. If data are unavailable for estimating live fuel moisture, the following rough estimates (Table 6) can be used. Enter the live fuel moisture for Fire Models 2, 4, 5, 7 and 10 as Input 3 on the Fire behavior Worksheet on page B-5.

B-29

INPUT 4: Midflame Windspeed (MFWS), mi/h

Midflame wind is the wind which acts directly on the flaming fire front at the level of one half the flame height. Fire generated convective winds must be ignored.

You may take wind readings directly with a handheld anemometer or other measuring device; however, the readings must be taken far enough upwind of the fire to ensure that the wind is not influenced by convective indrafts.

If you choose to use a weather forecast to estimate windspeeds, you must determine whether the forecast is for 20-foot windspeeds or midflame windspeeds.

When midflame winds are forecast, enter them directly in Input 4 of the Fire Behavior Worksheet.

If the 20-foot winds are forecast (which they usually are), the midflame windspeed must be calculated. Use the Wind Adjustment Worksheet on page B-7 and complete the following Input and Output Values.

Enter midflame windspeed as Output 1 on the Wind Adjustment Worksheet and as Input 4 on the Fire Behavior Worksheet on page B-5.

B-30

INPUT

0 (Projection Pint)—Record the number of the projection point for which a fire behavior prediction is to be made.

1 (20-foot Windspeed)—Enter the 20-foot windspeed provided in the Special Weather Forecast.

2 (Fuel Model Number)—Enter one of the 13 FBPS fuel models.

3 (Wind Sheltering)—Using Diagram 1 on page B-32, determine whether fuels are: 1) unsheltered, 2) partially sheltered, 3) fully sheltered (open) or 4) fully sheltered (closed).

4 (Wind Adjustment Factor)—Using Table 7 on page B-33, select the appropriate adjustment factor for the specific fuel and sheltering condition.

OUTPUT

1 (Midflame Windspeed)—Multiply Input 1 x Input 4 on the Wind Adjustment Worksheet for the midflame windspeed.

Remember, for basic point source predictions the wind should be blowing within + 30 degrees of upslope.

B-31

DIAGRAM 1: 20-Foot Windspeed Adjusted to Midflame Windspeed Based on Overstory

B-32

INPUT 5: Slope (SL), %

Slope Determination Process

To use the Slope Worksheet on page B-7 complete the following Input and Output Items. Enter slope as Output 1 on the Slope Worksheet and as Input 5 on the Fire Behavior Worksheet on page B-5.

INPUT


1 (Contour Interval)—Determine the contour interval from the map; i.e., 40 ft. This is the elevation change between contour lines.

2 (Map Scale)—Determine the map scale; i.e., 1:24,000. This is the number of units on the map to ground distance in the same units; i.e., one inch on the map equals 24,000 inches on the ground.

3 (Conversion Factor)—Determine how many feet are in one inch of map distance; i.e., 1 inch = 2,000 ft. To determine this, measure the distance between section lines (east to west) in inches and tenths of an inch. Divide the number of feet in a mile (5,280) by the measured map distance for the mile in inches.

Choose an area with uniform contour line separation. From the lowest point on the slope, Point A, draw a line up the slope with the contour lines intersecting at right angles, to Point B.

4 (# of Contour Intervals)—Count the number of contour interspaces crossed between Points A and B.

5 (Rise in Elevation)—Determine vertical change in elevation by counting the contour interspaces between Points A and B. Multiply by the contour interval (Input 1); i.e., 40 ft x 11 contours = 440 ft.

B-35

6 (Map Distance)—Measure horizontal distance with a ruler in inches to the tenth of an inch.

7 (Horizontal Ground Distance)—Multiply the Map Distance (Input 6) by the conversion factor (Input 3); i.e., 0.5 in x 2,000 ft/in = 1,000 ft.

OUTPUT

1 (Slope)—Calculate slope by dividing rise (Input 5) by run (Input 7) on the Slope Worksheet and multiplying by 100; i.e., rise (Input 5) divided by run (Input 7) x 100 or 440 ft divided by 1,000 ft x 100 = 44%.

RISE Vertical Distance= x 100 = % SlopeRUN Horizontal Distance

This table allows the selection of conversion factors for different map scales.

B-36

INPUT 6: Effective Windspeed (EWS), mi/h

Effective windspeed is determined using the lower left quadrant of the nomogram of the fuel model being used. Enter slope (Input 5) on the horizontal axis, and the midflame windspeed (Input 4) from the Fire Behavior Worksheet on the right axis.

Interpolation between the midflame windspeed line may be necessary. Read the effective windspeed on the left side of the graph. Enter effective windspeed as Input 6 on the Fire Behavior Worksheet on page B-5.

B-37

FIRE BEHAVIOR OUTPUTS

Determine the Fire Behavior Output Items (1-9) listed below and enter them on the Fire Behavior Worksheet on page B-5.

OUTPUT 1: Rate of Spread (ROS), ch/h

Using the upper right quadrant (left vertical axis) of the nomogram and input items recorded on the Fire Behavior Worksheet, determine rate of spread. Tables 15 through 78 can also be used to approximate rate of spread.

OUTPUT 2: Heat per Unit Area (HA), Btu/sq ft

Using the upper right quadrant of the nomogram, determine heat per unit area from the lower axis.

OUTPUT 3: Fireline Intensity (FLI), Btu/ft/s

Using the upper right quadrant of the nomogram, determine fireline intensity along the curved lines.

OUTPUT 4: Flame Length (FL), ft

Using the upper right quadrant of the nomogram, determine the flame length along the curved lines. Flame length can also be approximated using Tables 15 through 78.

OUTPUT 5: Spread Distance (SD), ch

Rate of spread (Output 1) on the Fire Behavior Worksheet, multiplied by the hours in which a fire spreads at that rate, equals spread distance. Convert to map distance using the Map-Spread Worksheet as outlined on page 39.

B-38

1

Map-Spread Worksheet

Use the Map-Spread Worksheet on page B-8 and complete the following Input and Output Items to determine map-spread distance. Enter the map-spread distance as Output 1 on the Map-Spread Worksheet and as Output 5 on the Fire Behavior Worksheet on page B-5.

INPUT


1 (Rate of Spread)—Fire Behavior Worksheet, Output 1.

2 (Projection Time)—Hours or part of an hour in which a fire has spread.

3 (Spread Distance, ch)—Input 1 multiplied by Input 2.

4 (Spread Distance, ft)—Input 3 multiplied by 66 ft/ch.

5 (Map Scale)—Table 9 on page B-36.

6 (Conversion Factor)—Table 9.

OUTPUT

(Map Spread Distance)—Input 4 divided by Input 6.

B-39

OUTPUT 6 and 7: Projected Fire Perimeter (PER), ch and Fire Area (AC), ac

Use the Size Worksheet on page B-8 and complete the following Input and Output Items to determine fire perimeter and area. Enter perimeter as Output 1 on the Size Worksheet and as Output 6 on the Fire Behavior Worksheet on page B-5. Enter area as Output 2 on the Size Worksheet and as Output 7 on the Fire Behavior Worksheet on page B-5.

INPUT

0 (Projection Point)—Record the number of the projection point for which a fire behavior prediction has been made.

1 (Rate of Spread)—Output 1 from the Fire Behavior Worksheet.

2 (Effective Windspeed)—Input 6 from the Fire Behavior Worksheet.

3 (Projection Time)—The time in which a fire has spread.

4 (Spread Distance)—Input 1 multiplied by Input 3.

OUTPUT

1 (Perimeter)—From Table 10 using the spread distance (Input 4) and effective windspeed (Input 2) determine perimeter.

2 (Area)—From Table 11 using the spread distance (Input 4) and effective windspeed (Input 2) determine area (acres).

B-40

This table can be used to estimate the perimeter of a fire in chains from estimates of total spread distance (rate of spread x time) and effective windspeed. When the effective windspeed is an even number or when spread distance is not broken out, estimations can be made or interpolation may be necessary.

B-43

This table can be used to estimate the area (acres) from estimates of total spread distance (rate of spread x time) and effective windspeed. When the effective windspeed is an even number or when spread distance is not broken out, estimations can be made or interpolation may be necessary.

B-46

DIAGRAM 2—Approximate Fire Shapes for Various Effective Windspeeds

B-47

OUTPUT 8: Maximum Spotting Distance (SPOT), mi

The Spotting Worksheet is used to predict the distance a firebrand will travel from the originating torching tree. It does not apply to firebrands resulting from a running crown fire, but may be considered as a first approximation in such situations. Use the Spotting Worksheet and Nomograms 1 through 4 to determine Maximum Spotting Distance. Enter Maximum Spotting Distance on the Spotting Worksheet and as Output 8 on the Fire Behavior Worksheet on page B-5.

INPUT

1 (Torching Tree Height)—Actual height of torching tree.

2 (Torching Tree Species)—When species is not provided, select species based on crown shape and knowledge of firebrand production.

3 (Torching Tree DBH)—Diameter at breast height.

4 (Average Tree Cover Height)—Estimate average tree cover height downwind from the torching tree.

5 (Windspeed at 20-foot Height)—Use the forecasted 20foot windspeed. When gusts are indicated, using the maximum gust would provide the worst case distance.

OUTPUT

(Maximum Spotting distance)—Enter maximum spotting distance on the Spotting Worksheet.

Convert spotting distance to map distance using the Map-Spot Worksheet as outlined on page B-49.

B-48

Map-Spot Worksheet

Use the Map-Spot Worksheet on page B-9 and complete the following Input and Output Items to determine map-spot distance. Enter the map-spot distance as Output 1 on the Map-Spot Worksheet and under Output 8 on the Fire Behavior Worksheet on page B-5.

INPUT


1 (Spotting Distance, mi)—Record the Output from the Spotting Worksheet.

2 (Spotting Distance, ft)—Multiply mile distance in Input 1 by 5,280 to obtain feet.

3 (Map Scale)—Record the map scale taken from the map being used; e.g., 1:24,000.

4 (Conversion Factor)—See Table 9 on page B-36 for correct conversion factor; e.g., 2000.

OUTPUT

1 (Map Distance Spot)—Input 2 divided by Input 4.

B-49

NOMOGRAM 1—Flame Height

From Nomogram 1, determine flame height by using DBH and torching tree species. Enter flame height in Box B on the Spotting Worksheet.

B-50

NOMOGRAM 2—Flame Duration

From Nomogram 2, determine flame duration by using DBH and tree species. Enter flame duration on the Spotting Worksheet.

B-51

NOMOGRAM 3—Ratio of Lofted Firebrand Height to Flame Height

From Nomogram 3, determine ratio of lofted firebrand height to flame height. Use flame duration and ratio of tree height to flame height as inputs. Enter ratio of lofted firebrand height to flame height in Box C on the Spotting Worksheet.

B-52

NOMOGRAM 4—Maximum Spotting Distance

On the lower right-hand edge of Nomogram 4, locate the firebrand height. Proceed vertically to the effective tree cover height. Move left horizontally until you reach the treetop windspeed; move vertically down to the bottom axis and read the maximum spotting distance. Enter the maximum spotting distance on the Spotting Worksheet.

B-53

OUTPUT 9: Probability of Ignition (PIG), %

Use Table 12 on page B-55 and the dry bulb temperature (Input 2), shading (Input 8) and the fine dead fuel moisture (Output 1) from the Fine Dead Fuel Moisture/Probability of Ignition Worksheet to determine probability of ignition.

Enter probability of ignition as Output 2 on the worksheet. Also record it as Output 9 on the Fire Behavior Worksheet on page B-5.

B-54

B-56

Interpretaion of Fire Behavior Information

DIAGRAM 3—Fire Behavior Characteristics Chart (Light Fuel)

B-57

DIAGRAM 4—Fire Behavior Characteristics Chart (Heavy Fuel)

B-58

TABLE 14—Fire Suppression Interpretations¹

CAUTION: These are not guides to personal safety. Fires can be dangerous at any level of intensity. Wilson (1977) has shown that most fatalities occur in light fuels on small fires or isolated sections of large fires.

¹ Help in Making Fuel Management Decisions, 1975; Research Paper NC-112, USDA: Forest Service.

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SAFETYAND FIRE BEHAVIOR

• Probably the most important aspect of predicting fire behavior is to identify potentially dangerous fireline conditions.

• Be alert to all potentially dangerous situations and communicate the danger to all affected personnel.

• Know, remember, and use:

– THE STANDARD ORDERS (Inside Cover)

– THE 18 WATCHOUT SITUATIONS (Inside Cover)

– THE FOUR COMMON DENOMINATORS OF FIRE BEHAVIOR ON TRAGEDY AND NEAR-MISS FIRES (Inside Cover)

– DOWNHILL/INDIRECT LINE CONSTRUCTION GUIDELINES (Chapter 4)

– THE 9 URBAN WILDLAND “WATCHOUTS”

– LCES (LOOK OUTS, COMMUNICATIONS, ESCAPE ROUTES, AND SAFETY ZONES)

– LOOK UP, LOOK DOWN, LOOK AROUND

B-60

FIRE ENVIRONMENT FACTORS INDICATORS

Fuel Characteristics Continuous fine fuels CARRIER! Assess Heavy loading of dead and down

Ladder Fuels Tight crown spacing (

FIRE ENVIRONMENT FACTORS INDICATORS

Wind Surface winds above 10 mi/h Observe Lenticular clouds

High, fast moving clouds Approaching cold front Cumulonimbus development Sudden calm Battling winds

Stability Clear visibility Observe Gusty winds and dust devils

Cumulus clouds Castellatus clouds in the a.m. Smoke rises straight up Inversion beginning to lift Thermal belt

Fire Behavior Leaning column Watch Sheared column

Well developed column Trees torching Smoldering fires picking up Small firewhirls beginning Frequent spot fires

Remember to Expect Diurnal Changes!

•RH• •Winds• •Temperature• •Stability•

• Indicators may vary in different regions and fuel types. • Ask questions in unfamiliar situations.

B-62

Tables 15 through 78—Rate of Spread and Flame Length Tables by Fuel Type and Percent Slope

NOTE: Tables 15 through 78 for ROS and FL (Output Items 1 and 4) on the Fire Behavior Worksheet reflect slope classes 0, 30, 45, 60 and 90 percent. You may use the slope class closest to the actual slope recorded (for Input Item 5) or interpolate between the slope class.

B-63

TABLE 40b: FUEL MODEL 6—30% SLOPE

B-85

B-124

CoverNWCG FIRELINE HANDBOOK. APPENDIX B. FIRE BEHAVIOR. PURPOSE FIRE BEHAVIOR WORKSHEET INPUT 0: Projection Point (PP) INPUT 1: Fuel Model (Model #) INPUT 2: Fine Dead Fuel Moisture (1-H FDFM), % INPUT 3: Live Fuel Moisture (LFM), % INPUT 4: Midflame Windspeed (MFWS), mi/h INPUT 5: Slope (SL), % INPUT 6: Effective Windspeed (EWS), mi/h FIRE BEHAVIOR OUTPUTS OUTPUT 1: Rate of Spread (ROS), ch/h OUTPUT 2: Heat per Unit Area (HA), Btu/sq ft OUTPUT 3: Fireline Intensity (FLI), Btu/ft/s OUTPUT 4: Flame Length (FL), ft OUTPUT 5: Spread Distance (SD), ch OUTPUT 6 and 7: Projected Fire Perimeter (PER), ch and Fire Area (AC), ac OUTPUT 8: Maximum Spotting Distance (SPOT), mi OUTPUT 9: Probability of Ignition (PIG), % Interpretaion of Fire Behavior InformationSAFETYAND FIRE BEHAVIOR

nwcg fireline handbook - appendix b · 2015. 9. 15. · nwcg fireline handbook appendix b fire...

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